Changes in parasite virulence induced by the disruption of a single member of the 235 kDa rhoptry protein multigene family of Plasmodium yoelii

Invasion of the erythrocyte by the merozoites of the malaria parasite is a complex process involving a range of receptor-ligand interactions. Two protein families termed Erythrocyte Binding Like (EBL) proteins and Reticulocyte Binding Protein Homologues (RH) play an important role in host cell recognition by the merozoite. In the rodent malaria parasite, Plasmodium yoelii, the 235 kDa rhoptry proteins (Py235) are coded for by a multigene family and are members of the RH. In P. yoelii Py235 as well as a single member of EBL have been shown to be key mediators of virulence enabling the parasite to invade a wider range of host erythrocytes. One member of Py235, PY01365 is most abundantly transcribed in parasite populations and the protein specifically binds to erythrocytes and is recognized by the protective monoclonal antibody 25.77, suggesting a key role of this particular member in virulence. Recent studies have indicated that overall levels of Py235 expression are essential for parasite virulence. Here we show that disruption of PY01365 in the virulent YM line directly impacts parasite virulence. Furthermore the disruption of PY01365 leads to a reduction in the number of schizonts that express members of Py235 that react specifically with the mcAb 25.77. Erythrocyte binding assays show reduced binding of Py235 to red blood cells in the PY01365 knockout parasite as compared to YM. While our results identify PY01365 as a mediator of parasite virulence, they also confirm that other members of Py235 are able to substitute for PY01365.     

NMR solution structure of NBD94(483-502) of the nucleotide-binding domain of the Plasmodium yoelii reticulocyte-binding protein Py235

Invasion of the erythrocyte by the invasive form of the malaria parasite, the merozoite, is a complex process involving numerous parasite proteins. The reticulocyte-binding protein homologues (RH) family of merozoite proteins has been previously shown to play an important role in the invasion process. Previously, it has been shown that the RH proteins of Plasmodium yoelii, Py235, play a role as an ATP/ADP sensor. Binding of Py235 to the erythrocyte surface is increased in the presence of ATP, while ADP has an inhibitory effect. The sensor domain of Py235 is called NBD94 and the segment that has been shown to covalently bind the adenine nucleotide is made up by the residues (483) FNEIKEKLKHYNFDDFVKEE(502) . Here, we report on the solution nuclear magnetic resonance structure of this peptide (NBD94(483-502) ) showing the presence of an α-helix between amino acid residues 485 and 491. The N- and C-terminal segments of the structure bend at tyrosine 493, a residue important for ATP binding. Importantly, erythrocyte-binding assays demonstrate that NBD94(483-502) can directly interfere with the binding of native Py235 to erythrocytes, suggesting a direct role of this region in erythrocyte binding. The data will provide the foundation for future studies to identify new compounds that directly interfere with the invasion process.     

Plasmodium yoelii: combinatorial expression of variants of the 235 kDa rhoptry antigen during infection

The 235 kDa rhoptry protein Py235 of Plasmodium yoelii, has been implicated in erythrocyte invasion by the merozoite forms of the parasite. Py235 is encoded by a large, highly polymorphic gene family, members of which appear to be differentially transcribed. However, it is not clear how many variants are expressed at the protein level during an infection cycle and whether or not these variants are expressed selectively or combinatorially. Certain monoclonal antibodies to Py235 have been shown to attenuate parasite virulence upon passive transfer into mice, suggesting that this antigen or its derivatives may be useful vaccine candidates. To provide a basis for this, we sought to identify those variants that are recognised by the host immune system, and to establish the pattern of expression of the antigen in mice during infection. Using Py235 monoclonal antibodies as probes, we isolated distinct antigenic variants from an expression library, suggesting that the antigen repertoire is potentially large and that different Py235 variants may be produced during infection. The implications of these observations are discussed with respect to the ability of a cloned parasite line to express distinct antigenic variants in vivo.     

Malaria multigene families: the price of chronicity

In this article, Georges Snounou, William Jarra and Peter Preiser discuss the survival strategy of malaria parasites in the light of a novel mechanism of clonal phenotypic variation recently described for a multigene family of Plasmodium yoelii yoelii. The 235 kDa rhoptry proteins (Py235) encoded by these genes may be involved in the selection of red blood cells for invasion by merozoites. The new mechanism may explain the ability of individual parasites to adapt to natural variations in red blood cell subsets, while ensuring that sufficient merozoites escape immune attack, thus maintaining a chronic infection for extended periods. This counterpoints the antigenic variation exemplified by PfEMP1 proteins (a large family of proteins derived from P. falciparum), which operates at the population level. The possibility of manipulating the expression of functionally similar genes in other Plasmodium species could lead to therapies aimed at reducing clinical severity without compromising the acquisition and maintenance of immunity.     

Delineation of epitopes on the Py235 rhoptry antigen of Plasmodium yoelii YM

The 235-kDa antigenic rhoptry protein Py235 of Plasmodium yoelii is encoded by a large, highly polymorphic gene family. Monoclonal antibodies to some of these antigens have been shown to attenuate the virulence of the lethal YM strain of the parasite, converting a potentially fatal YM infection to a fulminating one typical of the nonlethal 17X strain, by inducing a switch in target cell preference from mature red blood cells to reticulocytes. The reason for this is not known but would suggest that antigenic determinants of Py235 may be useful in or as subunit vaccines. To identify such determinants, we constructed an epitope expression library of one Py235 variant and screened the library with the antibodies. Thus, we mapped 5- and 12-amino acid epitopes to the C-terminus of the antigen. Both epitopes were more reactive with protective than with nonprotective monoclonal antibodies. This may explain the differential protection conferred by these antibodies upon their passive transfer into mice.     

Differential induction of TGF-beta regulates proinflammatory cytokine production and determines the outcome of lethal and nonlethal Plasmodium yoelii infections

Transforming growth factor-beta is an essential moderator of malaria-induced inflammation in mice. In this study, we show that the virulence of malaria infections is dependent upon the cellular source of TGF-beta and the timing of its production. C57BL/6 mice infected with a nonlethal (Py17X) strain of Plasmodium yoelii produce TGF-beta from 5 days postinfection; this correlates with resolution of parasitemia, down-regulation of TNF-alpha, and full recovery. In contrast, infection with the lethal strain Py17XL induces high levels of circulating TGF-beta within 24 h; this is associated with delayed and blunted IFN-gamma and TNF-alpha responses, failure to clear parasites, and 100% mortality. Neutralization of early TGF-beta in Py17XL infection leads to a compensatory increase in IL-10 production, while simultaneous neutralization of TGF-beta and IL-10R signaling leads to up-regulation of TNF-alpha and IFN-gamma, prolonged survival in all, and ultimate resolution of infection in 40% of Py17XL-infected animals. TGF-beta production can be induced in an Ag-specific manner from splenocytes of infected mice, and by cross-linking surface CTLA-4. CD25(+) and CD8(+) cells are the primary source of TGF-beta following Py17X stimulation of splenocytes, whereas Py17XL induces significant production of TGF-beta from adherent cells. In mice immunized against Py17XL, the early TGF-beta response is inhibited and is accompanied by significant up-regulation of IFN-gamma and TNF-alpha and rapid resolution of challenge infections.     

CTLA-4 blockade differentially influences the outcome of non-lethal and lethal Plasmodium yoelii infections

An immune response against malaria has to be tightly controlled. The production of pro-inflammatory cytokines is required to control parasites but the same cytokines are also involved in severe malaria. We have shown that CTLA-4 expression during Plasmodium berghei malaria dampens the immune response. This strain provokes a pro-inflammatory immune response that is associated with the pathology of cerebral malaria. Accordingly a blockade of CTLA-4 during the blood-stage of P. berghei malaria leads to an exacerbation of disease. To analyze the effects of a CTLA-4 blockade in a malaria model which is not prone to immune pathology we employed P. yoelii infection. Blood-stage infection led to a rapid induction of CTLA-4 on T cells. Using the non-lethal P. yoelii strain Py17NL we found that a blockade of CTLA-4 resulted in an increased T cell activation and IFN-gamma production, which was accompanied by a lower peak parasitemia and earlier parasite clearance. In contrast, blockade of CTLA-4 during infection with a P. yoelii strain exhibiting a higher parasitemia induced markedly increased serum-levels of TNF-alpha, which was associated with severe inflammation and reduced survival.     

Plasmodium yoelii inhibitor of cysteine proteases is exported to exomembrane structures and interacts with yoelipain‐2 during asexual blood‐stage development

Plasmodium falciparum (Pf) blood stages express falstatin, an inhibitor of cysteine proteases (ICP), which is implicated in regulating proteolysis during red blood cell infection. Recent data using the Plasmodium berghei rodent malaria model suggested an additional role for ICP in the infection of hepatocytes by sporozoites and during liver‐stage development. Here we further characterize the role of ICP in vivo during infection with Plasmodium yoelii (Py) and Pf. We found that Py‐ICP was refractory to targeted gene deletion indicating an essential function during asexual blood‐stage replication, but significant downregulation of ICP using a regulated system did not impact blood‐stage growth. Py‐ICP localized to vesicles within the asexual blood‐stage parasite cytoplasm, as well as the parasitophorous vacuole, and was exported to dynamic exomembrane structures in the infected RBC. In sporozoites, expression was observed in rhoptries, in addition to intracellular vesicles distinct from TRAP containing micronemes. During liver‐stage development, Py‐ICP was confined to the parasite compartment until the final phase of liver‐stage development when, after parasitophorous vacuolemembrane breakdown, it was released into the infected hepatocyte. Finally, we identified the cysteine protease yoelipain‐2 as a binding partner of Py‐ICP during blood‐stage infection. These data show that ICP may be important in regulating proteolytic processes during blood‐stage development, and is likely playing a role in liver stage‐hepatocyte interactions at the time of exoerythrocytic merozoite release.     

Malaria: an intra-erythrocytic neoplasm?

Drug resistance is a serious problem in malaria, and prospects for new drugs are not optimistic. In 1963, the US Army began a huge programme to develop new antimalarials; they screened over 235 000 compounds, but very few were sufficiently active and safe for use in humans. Part of the problem is that not enough is known about the biochemical properties of malaria parasites, especially the metabolic differences between them and their host cells which could offer targets for specific chemotherapy. An important characteristic of malaria infection is the rapid growth of the parasite population, and changes in host metabolism that result from this. A similar effect occurs in many cancers. In this article, Ya Zhang argues that malaria parasites also have metabolic similarities with tumour cells, and suggests that careful comparison of these two could provide insight for new drug development.     

Coinfection with nonlethal murine malaria parasites suppresses pathogenesis caused by Plasmodium berghei NK65

Mixed infection with different Plasmodium species is often observed in endemic areas, and the infection with benign malaria parasites such as Plasmodium vivax or P. malariae has been considered to reduce the risk of developing severe pathogenesis caused by P. falciparum. However, it is still unknown how disease severity is reduced in hosts during coinfection. In the present study, we investigated the influence of coinfection with nonlethal parasites, P. berghei XAT (Pb XAT) or P. yoelii 17X (Py 17X), on the outcome of P. berghei NK65 (Pb NK65) lethal infection, which caused high levels of parasitemia and severe pathogenesis in mice. We found that the simultaneous infection with nonlethal Pb XAT or Py 17X suppressed high levels of parasitemia, liver injury, and body weight loss caused by Pb NK65 infection, induced high levels of reticulocytemia, and subsequently prolonged survival of mice. In coinfected mice, the immune response, including the expansion of B220(int)CD11c(+) cells and CD4(+) T cells and expression of IL-10 mRNA, was comparable to that in nonlethal infection. Moreover, the suppression of liver injury and body weight loss by coinfection was reduced in IL-10(-/-) mice, suggesting that IL-10 plays a role for a reduction of severity by coinfection with nonlethal malaria parasites.     

Plasmodium yoelii: effects of red blood cell modification and antibodies on the binding characteristics of the 235-kDa rhoptry protein

The 235-kDa rhoptry protein of the rodent malaria parasite Plasmodium yoelii yoelii was shown to bind to the surface of mouse red blood cells in a calcium-independent process, using a erythrocyte-binding assay. This binding is affected by modification of the surface of the red blood cells by enzymatic treatment. Chymotrypsin and trypsin but not neuraminidase treatment of the erythrocytes significantly reduced the binding of the 235-kDa proteins. The binding of an unrelated 135-kDa protein was abolished by treatment with chymotrypsin. Although the 235-kDa proteins bind to both reticulocytes and mature red blood cells, the binding to mature cells was more pronounced. In the presence of hyperimmune infection serum or specific polyclonal antibodies to the 235-kDa protein its binding to erythrocytes was reduced, further demonstrating the specificity of this ligand-receptor interaction.     

Malaria impairs resistance to Salmonella through heme- and heme oxygenase-dependent dysfunctional granulocyte mobilization

In sub-Saharan Africa, invasive nontyphoid Salmonella (NTS) infection is a common and often fatal complication of Plasmodium falciparum infection. Induction of heme oxygenase-1 (HO-1) mediates tolerance to the cytotoxic effects of heme during malarial hemolysis but might impair resistance to NTS by limiting production of bactericidal reactive oxygen species. We show that co-infection of mice with Plasmodium yoelii 17XNL (Py17XNL) and Salmonella enterica serovar Typhimurium 12023 (Salmonella typhimurium) causes acute, fatal bacteremia with high bacterial load, features reproduced by phenylhydrazine-induced hemolysis or hemin administration. S. typhimurium localized predominantly in granulocytes. Py17XNL, phenylhydrazine and hemin caused premature mobilization of granulocytes from bone marrow with a quantitative defect in the oxidative burst. Inhibition of HO by tin protoporphyrin abrogated the impairment of resistance to S. typhimurium by hemolysis. Thus, a mechanism of tolerance to one infection, malaria, impairs resistance to another, NTS. Furthermore, HO inhibitors may be useful adjunctive therapy for NTS infection in the context of hemolysis.     

Optimization of plasmepsin inhibitor by focusing on similar structural feature with chloroquine to avoid drug-resistant mechanism of Plasmodium falciparum

The plasmepsins are specific aspartic proteases of the malaria parasite and a potential target for developing new antimalarial agents. Our previously reported peptidomimetic plasmepsin inhibitor with modified 2-aminoethylamino substituent, KNI-10740, was tested against chloroquine sensitive Plasmodium falciparum, D6, to be highly potent, however, the inhibitor exhibited about 5 times less activity against multi-drug resistant parasite (TM91C235). We hypothesized the potency reduction resulted from structural similarity between 2-aminoethylamino substituent of KNI-10740 and chloroquine. Then, we modified the moiety and finally identified compound 15d (KNI-10823), that could avoid drug-resistant mechanism of TM91C235 strain.     

Endothelial cell tumors develop in transgenic mice carrying polyoma virus middle T oncogene

Inoculation of newborn mice with the murine polyoma (Py) virus leads to tumor formation in a wide range of tissues. In order to investigate viral oncogenesis, we generated transgenic mice carrying either the Py large T antigen (LT) gene or the Py middle T antigen (MT) gene linked to Py early region regulatory sequences. While Py LT mice exhibit no phenotype, Py MT mice develop multifocal tumors of the vascular endothelium. These hemangiomas are lethal to the animals and can be passaged in vivo. Transgene RNAs and protein are present in both hemangiomas and the testes of these mice, and the Py middle T protein in both tissues is complexed to a cellular tyrosine kinase. The expression of complexed middle T protein in both tumorigenic endothelial cells and unperturbed testes implies that endothelial cells may be particularly susceptible to the action of the middle T oncogene. These observations indicate that Py middle T disrupts the normal strict controls on vascular growth, and suggest that Py MT transgenic mice will provide a model for studying the control of angiogenesis.     

Cell penetration and trafficking of polyomavirus

The murine polyomavirus (Py) enters mouse fibroblasts and kidney epithelial cells via an endocytic pathway that is caveola-independent (as well as clathrin-independent). In contrast, uptake of simian virus 40 into the same cells is dependent on caveola. Following the initial uptake of Py, both microtubules and microfilaments play roles in trafficking of the virus to the nucleus. Colcemid, which disrupts microtubules, inhibits the ability of Py to reach the nucleus and replicate. Paclitaxel, which stabilizes microtubules and prevents microtubule turnover, has no effect, indicating that intact but not dynamic microtubules are required for Py infectivity. Compounds that disrupt actin filaments enhance Py uptake while stabilization of actin filaments impedes Py infection. Virus particles are seen in association with actin in cells treated with microfilament-disrupting or filament-stabilizing agents at levels comparable to those in untreated cells, suggesting that a dynamic state of the microfilament system is important for Py infectivity.     

DNA sequence requirements for replication of polyomavirus DNA in vivo and in vitro.

Cell extracts of FM3A mouse cells replicate polyomavirus (Py) DNA in the presence of immunoaffinity-purified Py large T antigen, deoxynucleoside triphosphates, ATP, and an ATP-generating system. This system was used to examine the effects of mutations within or adjacent to the Py core origin (ori) region in vitro. The analysis of plasmid DNAs containing deletions within the early-gene side of the Py core ori indicated that sequences between nucleotides 41 and 57 define the early boundary of Py DNA replication in vitro. This is consistent with previously published studies on the early-region sequence requirements for Py replication in vivo. Deleting portions of the T-antigen high-affinity binding sites A and B (between nucleotides 57 and 146) on the early-gene side of the core ori led to increased levels of replication in vitro and to normal levels of replication in vivo. Point mutations within the core ori region that abolish Py DNA replication in vivo also reduced replication in vitro. A mutant with a reversed orientation of the Py core ori region replicated in vitro, but to a lesser extent that wild-type Py DNA. Plasmids with deletions on the late-gene side of the core ori, within the enhancer region, that either greatly reduced or virtually abolished Py DNA replication in vivo replicated to levels similar to those of wild-type Py DNA plasmids in vitro. Thus, as has been observed with simian virus 40, DNA sequences needed for Py replication in vivo are different from and more stringent than those required in vitro.